2016/2017

2016/2017

DM270

ING-INF/04 (AUTOMATICS)

DEPARTMENT OF ELECTRICAL,COMPUTER AND BIOMEDICAL ENGINEERING

INDUSTRIAL AUTOMATION ENGINEERING

PERCORSO COMUNE

1°

1st semester (26/09/2016 - 13/01/2017)

6

45 lesson hours

ITALIAN

WRITTEN AND ORAL TEST

DE NICOLAO GIUSEPPE (titolare) - 6 ECTS

Basic notions of set theory, logic, calculus, function maximization.

Knowledge of basic notions of probability and statistics. Ability to solve data analysis and estimation problems ranging from model formulation to the use of computer tools (Matlab) for parameter estimation and model simulation.

System Identification deals with methodologies that enable the construction of mathematical models of systems and signals based on experimental data. In presence of complex systems whose behavior can be hardly reduced to known "laws of nature", the use of identification techniques is often the only way to obtain models to be used in the context of forecasting, simulation, and control. The methods presented in the course are widely used in heterogeneous fields such as automation, biomedical engineering, econometry, hydrology, geophysics and telecommunications. Some basic notions of probability, estimation theory and stochastic processes are recalled. The main properties (stability, input-output description in the time and frequenct domains) of linear discrete-time systems are introduced. In the context of parametric estimation, the issues of model validation and model complexity are extensively discussed. Neural based identification is also illustrated and discussed, pointing out pros and cons with respect to standard approaches. The study of dynamic systems addresses three main topics: the optimal prediction of stationary stochastic processes (Wiener filtering), the identification of linear discrete-time systems, and spectral estimation (both nonparametric and maximum-entropy).

Probability: basic notions

probability notion;
independence, conditional probability, total probability and Bayes theorems;
Bernoulli trials, Poisson events;
the notion of random variable (R.V.), cumulative distribution function, probability density function, functions on one R.V.;
mode, median, moments of a R.V.;
joint random variables: distribution, density, moments, independence, incorrelation, functions of random variables;
Law of Lrge Numbers, Gaussian R.V., Central Limit Theorem.

Statistics: basic notions

notion of estimator; properties of estimators;
sample moments and their main properties;
confidence interval for the sample mean, Student's t.

Identification of linear-in-parameter models:

the least squares method, normal equations, identifiability;
Best Linear Unbiased Estimator: estimator, variance of parameters;
validation and choice of complexity: chi-square test, F-test, FPE, AIC, and MDL criteria.

Lectures, Practical class

Lecture notes (http://sisdin.unipv.it/labsisdin/teaching/teaching.php).

M. Bramanti. Calcolo delle probabilità e statistica. Esculapio.

A. Papoulis. Probability, Random Variables, and Stochastic Processes. McGraw-Hill.

L. Ljung. System Identification: Theory for the User. Prentice-Hall.

Written examination

Written examination